// Copyright 2021 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package types2 import ( "cmd/compile/internal/syntax" "strconv" ) // ---------------------------------------------------------------------------- // API // A Struct represents a struct type. type Struct struct { fields []*Var tags []string // field tags; nil if there are no tags } // NewStruct returns a new struct with the given fields and corresponding field tags. // If a field with index i has a tag, tags[i] must be that tag, but len(tags) may be // only as long as required to hold the tag with the largest index i. Consequently, // if no field has a tag, tags may be nil. func NewStruct(fields []*Var, tags []string) *Struct { var fset objset for _, f := range fields { if f.name != "_" && fset.insert(f) != nil { panic("multiple fields with the same name") } } if len(tags) > len(fields) { panic("more tags than fields") } return &Struct{fields: fields, tags: tags} } // NumFields returns the number of fields in the struct (including blank and embedded fields). func (s *Struct) NumFields() int { return len(s.fields) } // Field returns the i'th field for 0 <= i < NumFields(). func (s *Struct) Field(i int) *Var { return s.fields[i] } // Tag returns the i'th field tag for 0 <= i < NumFields(). func (s *Struct) Tag(i int) string { if i < len(s.tags) { return s.tags[i] } return "" } func (s *Struct) Underlying() Type { return s } func (s *Struct) String() string { return TypeString(s, nil) } // ---------------------------------------------------------------------------- // Implementation func (check *Checker) structType(styp *Struct, e *syntax.StructType) { if e.FieldList == nil { return } // struct fields and tags var fields []*Var var tags []string // for double-declaration checks var fset objset // current field typ and tag var typ Type var tag string add := func(ident *syntax.Name, embedded bool, pos syntax.Pos) { if tag != "" && tags == nil { tags = make([]string, len(fields)) } if tags != nil { tags = append(tags, tag) } name := ident.Value fld := NewField(pos, check.pkg, name, typ, embedded) // spec: "Within a struct, non-blank field names must be unique." if name == "_" || check.declareInSet(&fset, pos, fld) { fields = append(fields, fld) check.recordDef(ident, fld) } } // addInvalid adds an embedded field of invalid type to the struct for // fields with errors; this keeps the number of struct fields in sync // with the source as long as the fields are _ or have different names // (issue #25627). addInvalid := func(ident *syntax.Name, pos syntax.Pos) { typ = Typ[Invalid] tag = "" add(ident, true, pos) } var prev syntax.Expr for i, f := range e.FieldList { // Fields declared syntactically with the same type (e.g.: a, b, c T) // share the same type expression. Only check type if it's a new type. if i == 0 || f.Type != prev { typ = check.varType(f.Type) prev = f.Type } tag = "" if i < len(e.TagList) { tag = check.tag(e.TagList[i]) } if f.Name != nil { // named field add(f.Name, false, f.Name.Pos()) } else { // embedded field // spec: "An embedded type must be specified as a type name T or as a // pointer to a non-interface type name *T, and T itself may not be a // pointer type." pos := syntax.StartPos(f.Type) name := embeddedFieldIdent(f.Type) if name == nil { check.errorf(pos, "invalid embedded field type %s", f.Type) name = &syntax.Name{Value: "_"} // TODO(gri) need to set position to pos addInvalid(name, pos) continue } add(name, true, pos) // Because we have a name, typ must be of the form T or *T, where T is the name // of a (named or alias) type, and t (= deref(typ)) must be the type of T. // We must delay this check to the end because we don't want to instantiate // (via under(t)) a possibly incomplete type. embeddedTyp := typ // for closure below embeddedPos := pos check.later(func() { t, isPtr := deref(embeddedTyp) switch t := under(t).(type) { case *Basic: if t == Typ[Invalid] { // error was reported before return } // unsafe.Pointer is treated like a regular pointer if t.kind == UnsafePointer { check.error(embeddedPos, "embedded field type cannot be unsafe.Pointer") } case *Pointer: check.error(embeddedPos, "embedded field type cannot be a pointer") case *TypeParam: check.error(embeddedPos, "embedded field type cannot be a (pointer to a) type parameter") case *Interface: if isPtr { check.error(embeddedPos, "embedded field type cannot be a pointer to an interface") } } }) } } styp.fields = fields styp.tags = tags } func embeddedFieldIdent(e syntax.Expr) *syntax.Name { switch e := e.(type) { case *syntax.Name: return e case *syntax.Operation: if base := ptrBase(e); base != nil { // *T is valid, but **T is not if op, _ := base.(*syntax.Operation); op == nil || ptrBase(op) == nil { return embeddedFieldIdent(e.X) } } case *syntax.SelectorExpr: return e.Sel case *syntax.IndexExpr: return embeddedFieldIdent(e.X) } return nil // invalid embedded field } func (check *Checker) declareInSet(oset *objset, pos syntax.Pos, obj Object) bool { if alt := oset.insert(obj); alt != nil { var err error_ err.errorf(pos, "%s redeclared", obj.Name()) err.recordAltDecl(alt) check.report(&err) return false } return true } func (check *Checker) tag(t *syntax.BasicLit) string { // If t.Bad, an error was reported during parsing. if t != nil && !t.Bad { if t.Kind == syntax.StringLit { if val, err := strconv.Unquote(t.Value); err == nil { return val } } check.errorf(t, invalidAST+"incorrect tag syntax: %q", t.Value) } return "" } func ptrBase(x *syntax.Operation) syntax.Expr { if x.Op == syntax.Mul && x.Y == nil { return x.X } return nil }